Ceramic springs are manufactured using advanced ceramic materials as their primary components. By carefully controlling the composition and structure, these ceramic materials exhibit elasticity, challenging the conventional perception of ceramics as "brittle" and "hard" materials. In addition to meeting the standards of metal springs in terms of compression cycle performance, ceramic springs possess exceptional properties such as high temperature resistance, corrosion resistance, and resistance to water and oxygen.

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In comparison to metal springs, ceramic springs offer several advantages. While metal springs can only withstand temperatures up to 700°C and cannot operate for extended periods under such conditions, ceramic springs can easily surpass this temperature limit and endure high temperatures exceeding 1400°C. This makes them suitable for applications in aerospace and new energy batteries, where they can bear significant responsibilities in extreme environments characterized by high temperatures, water, oxygen, and corrosive elements. Furthermore, ceramic springs have successfully withstood numerous compression fatigue tests.



Ceramics encompass not only the renowned porcelain that symbolizes traditional Chinese cultural heritage, but also ceramic springs, which introduce elasticity to ceramics. Currently, the highest known record for elastic compression in ceramics stands at 20%.